Genetic method

ABSTRACT

The present invention describes a method of increasing plan yield. Also described are DNA constructs comprising DNA sequences coding for proteins involved in sucrose transport, metabolism and uptake operably linked to controllable promoter regions and plants transformed with said constructs. More particularly a method for the controlled production of said proteins resulting in an alteration in plant growth characteristics, flowering time and in yield is described.

The present invention relates to a method of increasing plant yield, toDNA constructs comprising DNA sequences coding for proteins involved insucrose transport, metabolism and uptake operably linked to controllablepromoter regions and to plants transformed with said constructs. Moreparticularly the present invention relates to the controlled productionof said proteins resulting in an alteration in plant growthcharacteristics, flowering time and in yield.

Photosynthesis is the major source of energy used to support biologicalprocesses in higher plants. The photosynthesising cells serve asimportant sources of photoassimilates or organic compounds produced inthe plant by photosynthesis. Most fixed organic carbon is translocatedfrom the source photosynthetic tissue to the non-photosynthetic organswhich are known as the sink and this is the area in the plant where thetranslocated nutrients are either used or stored. The principal productof carbon fixation during the photosynthetic reaction is thedisaccharide sucrose.

We have now found that by controlling the expression of DNA sequencescoding for proteins involved in the transport, metabolism and uptake ofsucrose using inducible promoter systems, it is possible to alter thesucrose levels in the plant in a controlled manner to produce thedesired change in flowering and/or plant weight and/or height at theappropriate stage in plant growth whereby any effects deleterious to theplant are avoided and the overall yield of the plant is increased. Theuse of controllable promoter regions permits the expression of said DNAsequences to be regulated in a very precise way such that the optimallevel of expression, the optimal time at which the DNA sequence isexpressed and the optimal location in the plant may be determined.

According to a first aspect of the present invention there is provided amethod of increasing the yield of a plant comprising transforming aplant with a DNA construct comprising one or more DNA sequence(s) codingfor a protein involved in sucrose sensing, transport, metabolism and/oruptake operably linked to a controllable promoter region and optionallyoperably linked to a transcription terminator and controlling the level,time and spatial location of expression of said DNA sequence(s) fromsaid controllable promoter region by application of an external chemicalinducer whereby the yield of said transgenic plant is increased.

According to a preferred embodiment of the first aspect of the presentinvention there is provided a method of increasing the yield of a plantby selectively increasing the importation of fixed carbon intophotosynthetically inactive sink tissues comprising transforming a plantwith a DNA construct comprising one or more DNA sequence(s) coding for aprotein involved in sucrose sensing, transport, metabolism and/or uptakeoperably linked to a controllable promoter region and optionallyoperably linked to a transcription terminator and controlling the level,time and spatial location of expression of said DNA sequence(s) fromsaid controllable promoter region by application of an external chemicalinducer whereby the transportation of fixed carbon fromphotosynthetically active source tissue to photosynthetically inactivesink tissue of said transgenic plant is selectively increased.

As used herein the term “source tissue” is used to denote thosephotosynthetically active tissues of the plant which are net exportersof fixed carbon and “sink tissue” denotes those photosyntheticallyinactive tissues of the plant which are net importers of fixed carbon.

It is economically and practically very desirable to be able to controlboth the ability to flower and the time of flowering of a plant. In someinstances it may be desirable to synchronise flowering or to switch onflowering early or to manipulate flowering behaviour to suit theconstraints imposed by growing in particular geographical areas.Generally an increase in the number of flowers is reflected in anincrease in the eventual yield from the plant due to the increase in thenumber of seeds.

Similarly, an increase in the fresh weight of a plant as measured by anincrease in leaf area results in an increase in yield due to theincrease in the photosynthetic capacity of the plant.

Yield depends upon at least two parameters:—(i) sink induction and (ii)sink growth. Amongst other factors, sink induction can be stimulated byreducing the assimilate supply. This happens when invertase, forexample, is induced in leaves. Sink growth depends upon the amount ofassimilates allocated to the specific sink. This can be stimulated bysink-specific expression of the invertase. Since invertase activitynegatively effects starch synthesis, chemical control of invertaseexpression is clearly advantageous over its constitutive expression.

An increase sink supply is likely to result in larger tubers wheninvertase expression is induced. The early flowering phenotype is,however, believed to be explained by a transient shortage of assimilatesupply.

According to a second aspect of the present invention there is provideda method of controlling the flowering behaviour of a plant comprisingtransforming a plant with a DNA construct comprising one or more DNAsequence(s) coding for a protein involved in sucrose sensing, transport,metabolism and/or uptake operably linked to a controllable promoterregion and optionally operably linked to a transcription terminator andcontrolling the level, time and spatial location of expression of saidDNA sequence(s) from said controllable promoter region by application ofan external chemical inducer whereby the flowering behaviour of saidtransgenic plant is altered.

The method of controlling flowering behaviour may be used to speed upthe growth cycle of a plant such that more generations are produced.

The controllable promoter region in all aspects and embodiments of thepresent invention mentioned herein preferably comprises an inducibleswitch promoter system such as, for example, the alcA/alcR gene switchpromoter system described in published International Patent ApplicationNo. WO 93/21334; the GST promoter as described in publishedInternational Patent Application Nos. WO 90/08826 and WO 93/031294; andthe ecdysone switch system as described in published InternationalPatent Application No. WO 96/37609 the teachings of which areincorporated herein by reference. Such promoter systems are hereinreferred to as “switch promoters”. Switch promoter systems areparticularly suitable for use in the method of the present inventionsince they allow the expression of DNA sequences to be switched ondifferent parts of a transgenic plant at different times by means ofsequential induction where the chemical inducer can be applied to thedesired area of the plant at the desired stage of growth. For example,the switch chemical may be applied as a spray or vapour to all or partof the transgenic plant or as a root drench.

Examples of suitable switch chemicals are provided in the abovereferences describing the switch promoter systems and are illustrated inthe accompanying examples. The switch chemicals are desirablyagriculturally acceptable chemicals.

Inducible promoter systems preferably include one or two componentsystems. Systems comprising more than two components are, however, alsoincluded. The switch system may be driven by a constitutive promoter or,preferably, by a tissue or organ specific promoter whereby the targetgene is only switched on in a target tissue or organ.

The alcA/alcR switch promoter system is particularly preferred for usein all aspects of the present invention mentioned herein.

The alcA/alcR inducible promoter system is a two component systeminvolving DNA sequences coding for the alcA promoter and the alcRprotein, the expression of which is placed under the control of desiredpromoters. The alcR protein activates the alcA promoter in the presenceof inducer and any gene placed under the control of the alcA promoterwill therefore be expressed only in the presence of inducer. Thepromoter controlling expression of the alcR regulatory protein ispreferably be a tissue or organ selective promoter, such as a leaf ortuber specific promoter, such that alcR is produced and alcA activatedresulting in expression of the DNA sequence coding for the protein ofinterest only in selected parts of the plant such as for example theleaf, fruit, grain, endosperm or seed. When the method of the presentinvention is for use in cereal crops the expression of alcR is desirablycontrolled by a seed specific promoter; for use in grain the expressionof alcR is desirably controlled by promoters associated with genesinvolved in starch synthesis or with seed storage proteins and for usewith forage crops the expression of alcR is desirably controlled by leafspecific promoters. Examples of tissue or organ selective promoters arewell known in the art and include for example seed specific promoterssuch as the Ltp2 promoter ( Kalla et al, Plant J 6 (6) 849-60, (1994)),the zmGBS, the zmZ27, the osAGP and the osGT1 promoters ( Russell andFromm, Transgenic Res 1997, 6 (2) 157-68), the CMd promoter (Grosset etal, Plant Mol Biol 1997 34(2) 331-338), the glycinin A2Bla promoter,(Itoh et al Mol Gen Genet 1994 243(3) 353-357), the oleosin promoterfrom Brassica napus (Keddie et al Plant Molecular Biology 19 443-453,(1992)), the MatP6 oleosin promoter from cotton (Hughes et al, PlantPhysiol (1993) 101 697-698), the oleosin promoter from Arabidopsis (Plant et al, Plant Mol. Biol. 25 193-205 (1994)), the zein promoter(Ottoboni et al Plant Mol Biol (1993) 21, 765-778), and fruit and organspecific promoters such as the patatin promoter (Rocha-Sosa et al EMBO J8 23-30 1989), the promoter family associated withribulose-1,5-bisphosphate carboxylase/oxygenase small subunit genes fromtomato (Meier, Plant Physiol 107 (4) 1105-1118 (1995)), tomato rbcS3Band rbcS3C promoters (Carrasco Plant Mol Biol 21 (1) 1-15 (1993), theleaf promoter STL1 (Eckes et al Mol. Gen Genet 205 14-22 (1986)) and therolC promoters.

According to a further preferred embodiment of the present inventionthere is provided a method of increasing plant yield comprisingtransforming a plant with a DNA construct comprising one or more DNAsequence(s) coding for a protein involved in sucrose sensing, transport,metabolism and/or uptake operably linked to the alcA/alcR controllablepromoter region wherein the promoter controlling expression of the alcRregulatory protein is a tissue or organ specific promoter and isoptionally operably linked to a transcription terminator and controllingthe level, time and spatial location of expression of said DNAsequence(s) from said controllable promoter region by application of anexternal chemical inducer whereby the yield of said transgenic plant isincreased.

Examples of DNA sequences which may be used in the method of the presentinvention to increase plant yield and to control flowering behaviourinclude those DNA sequences coding for proteins involved in thetransport, uptake and subsequent metabolism of sucrose e.g.phosphofructokinase, invertase and hexokinase; in sucrose biosynthesise.g. sucrose synthase, sucrose phosphate synthase andfructose-1,6-biphosphatase; in the transport of reserves during dormancysuch as in phloem loading e.g. ATPase and sucrose and hexose transportproteins; in long distance phloem transport and in phloem unloading e.g.inorganic pyrophosphorylase (iPPase); in the utilisation of assimilatese.g. utilisation of sucrose-derived metabolites; in blocking starchsynthesis (indirectly leading to increased sucrose levels); andinvertase inhibitors.

The use of a controllable promoter region allows the production of theDNA sequence to be switched on in a controlled manner at the appropriatetime in the growth cycle of the plant. We have unexpectedly found thatthe controlled expression of an invertase gene using the alcA/alcRswitch promoter system leads to an increase in plant height, an increasein leaf size and to an increase of up to 10% in the fresh weight of aplant and accelerates the time at which the plants flower i.e the plantsflower early.

According to a another preferred embodiment of the present inventionthere is therefore provided a method of increasing plant yieldcomprising transforming a plant with a DNA construct comprising a DNAsequence coding for an invertase operably linked to a controllablepromoter region and optionally operably linked to a transcriptionterminator and controlling the level, time and spatial location ofexpression of said DNA sequence from said controllable promoter regionby application of an external chemical inducer whereby the yield of saidtransgenic plant is increased.

According to yet another preferred embodiment of the present inventionthere is therefore provided a method of controlling the floweringbehaviour of a plant comprising transforming a plant with a DNAconstruct comprising a DNA sequence coding for an invertase operablylinked to a controllable promoter region and optionally operably linkedto a transcription terminator and controlling the level, time andspatial location of expression of said DNA sequence from saidcontrollable promoter region by application of an external chemicalinducer whereby the flowering behaviour of said transgenic plant isaltered.

The invertase may be derived from mammalian, bacterial, yeast, fungal orplant sources and may be different types such as acid invertase orneutral invertase. Invertase may be directed to different cellularlocations such as the cell wall, the cytosol, the vacuole or apoplast bymeans of signal peptides (see Sonnewald el al. 1991 Plant J. 1:95-106).

According to a third aspect of the present invention there is provided aDNA construct comprising a DNA sequence coding for a protein involved insucrose metabolism, uptake and/or transport operably linked to acontrollable promoter region.

The DNA constructs according to the present invention may alsooptionally contain a transcription terminator sequence and/or atargeting sequence such that the invertase is targeted to a desiredlocation within the plant. Examples of transcription terminators includethe nopaline synthase transcription terminator and examples of suitabletargeting sequences include for example signal sequences and vacuolartargeting sequences

In a preferred embodiment of this aspect of the present invention theDNA sequence codes for invertase and the controllable promoter region isan inducible promoter region comprising the alcA/alcR switch promotersystem.

Plant cells may be transformed with recombinant DNA constructs accordingto a variety of known methods such as with Agrobacterium Ti plasmids,electroporation, microinjection, microprojectile gun. The transformedcells may then be regenerated into whole plants in which the new nuclearmaterial is stably incorporated into the genome. Some of the progeny ofthese primary transformants will inherit the recombinant DNA accordingto the present invention.

According to a fourth aspect of the present invention there is providedplant tissue transformed with a DNA construct comprising a DNA sequencecoding for a protein involved in sucrose metabolism, uptake and ortransport operably linked to a controllable promoter region and to theprogeny of said plants.

Examples of suitable plants the yield of which may be increased and theflowering behaviour of which may be controlled according to the methodsof the present invention and which may be transformed with DNAconstructs according to the present invention include, for example,monocotyledonous and dicotyledonous plants such as field crops, cereals,fruit and vegetables such as : canola, sunflower, tobacco, sugarbeet,cotton, soya, maize, wheat, barley, rice, sorghum, tomatoes, mangoes,peaches, apples, pears, strawberries, bananas, melons, potatoes, carrot,lettuce, cabbage and onion; trees such as eucalyptus and poplar treesand cut flowers and ornamentals.

The method of the present invention may be particularly useful forimproving the uniformity of banana fillings in a hand of bananas wherecommonly the banana fingers at the top of the hand fill first and splitwhile those at the bottom are not full enough. According to the methodof the present invention the sink strength of the bananas may be alteredsuch that fixed carbon from those at the top of the hand may be drawninto those bananas at the bottom leading to a more uniform hand size.

The present invention is further illustrated only by way of example withreference to the following Examples and Figures in which:

FIG. 1 shows invertase activity in source leaves of transgenicAlc:cytosolic invertase and Alc: cell wall invertase tobacco plantsfollowing ethanol induction

FIG. 2 shows a graphical representation of quantum yield of wild typeand transgenic tobacco plants at various time points after induction.

FIG. 3 shows a histogram analysis of invertase activity in transgenicplants at two different concentrations of ethanol (i.e. for wild type,alc:INV27, alc:INV10, alc:INV28 and 35ScytINV

FIG. 4 shows histogram analysis of a) invertase activity; b) freshweight; c) height and d) % flowering plants in wild type and transgenictobacco plants induced by ethanol (i.e. wild type, alc:rNV27, alc:INV10and alc:INV28)

FIG. 5 shows a photograph of Alc invertase lines 27, 28, 10 and wildtype A) no ethanol B) with ethanol

FIG. 6 shows transient expression of invertase increased flower numberin Alc:cyINV but not Alc:cwINV tobacco plants

FIG. 7 shows the alteration of flowering behaviour in both Alc:cyrNV andAlc:cwINV on expression of invertase

FIG. 8 shows transient expression of invertase leading to earlyflowering in tobacco plants

FIG. 9 shows the draft strategy for cloning an Alc GUS construct with anL700 promoter

FIG. 10 shows organ specific expression of L700::Alc:GUS tobacco plantsafter 48 hours induction

FIG. 11 shows the draft strategy for cloning an Alc GUS construct withpatatin B33 promoter

FIG. 12 shows a histogram analysis of GUS activity in wild type andtransgenic potato tubers 0 and 7 days after induction

FIG. 13 shows a histogram analysis of the levels of GUS activityobserved in tubers of potato transformed with a patatin:alc:GUSconstruct induced with ethanol

FIG. 14 shows tissue specific and ethanol inducible GUS expression intransgenic tobacco plants: tuber-specific expression of the alcR protein

FIG. 15 shows the plasmid construction of patatin B33::Alc:cwINV

FIG. 16 shows invertase activity in patatin:Alc:cwINV potato tubersinduced by ethanol

FIG. 17 shows carbohydrate content in Pat::cwINV and Pat::Alc:cw INVpotato growing tubers

FIG. 18 shows increased potato tuber size resulting from early inductionof apoplastic invertase expression

EXAMPLES

We have adapted the alc regulon of the ascomycete fungus A. nidulans,which has been well characterised ( Pateman et al, Proc. Roy. Soc.London B 217, 243 (1983), Creaser et al, Biochem J. 225 449 (1985),Lockington et al, Mol. Microbiol 1, 275 (1987), Felenbok et al, Gene 73,385 (1988), Felenbok et al, J. Biotechnol. 17, 11 (1991), Kulmberg etal, J. Biol. Chem 267, 21146 (1992), Kulmberg et al, Mol. Microbiol. 7847, (1993), and Fillinger and Felenbok, Mol. Microbiol 20 475 (1996)).From classical genetics, it has been assumed that this is aself-contained genetic system that controls the cellular response toethanol and other related chemicals. In A. nidulans, the alcA and aldAgenes encode alcohol dehydrogenase I and aldehyde dehydrogenase,respectively (Pateman et al, Proc. Roy. Soc. London B 217, 243 (1983),Creaser et al, Biochem J. 225 449 (1985), Lockington et al, Mol.Microbiol 1, 275 (1987), Felenbok et al, Gene 73, 385 (1988), Felenboket al, J. Biotechnol. 17, 11 (1991), Kulmberg et al, J. Biol. Chem 267,21146 (1992), Kulmberg et al, Mol. Microbiol. 7 847, (1993), andFillinger and Felenbok, Mol. Microbiol 20 475 (1996)). Both of thesegenes are regulated by the pathway-specific AlcR transcription factor(Pateman et al, Proc. Roy. Soc. London B 217, 243 (1983), Creaser et al,Biochem J. 225 449 (1985), Lockington et al, Mol. Microbiol 1, 275(1987), Felenbok et al, Gene 73, 385 (1988), Felenbok et al, J.Biotechnol. 17, 11 (1991), Kulmberg et al, J. Biol. Chem 267, 21146(1992), Kulmberg et al, Mol. Microbiol. 7 847, (1993), and Fillinger andFelenbok, Mol. Microbiol 20 475 (1996)). The AlcR protein binds tospecific sites within the alcA promoter region and, as we demonstratehere, must respond directly to the inducer molecule (Pateman et al,Proc. Roy. Soc. London B 217, 243 (1983), Creaser et al, Biochem J. 225449 (1985), Lockington et al, Mol. Microbiol 1, 275 (1987), Felenbok etal, Gene 73, 385 (1988), Felenbok et al, J. Biotechnol. 17, 11 (1991),Kulmberg et al, J. Biol. Chem 267, 21146 (1992), Kulmberg et al, Mol.Microbiol. 7 847, (1993), and Fillinger and Felenbok, Mol. Microbiol 20475 (1996)).

The alc regulon was considered suitable for a plant gene expressioncassette for a number of reasons. First, the minimal regulon wouldinclude only the alcR gene and the alcA promoter. Second, theevolutionary divergence between A. nidulans and higher plants would makeit unlikely that any plant homologues of the AlcR protein would activatethe promoter: AlcR contains a zinc binuclear cluster like Gal4 ( Patemanet al, Proc. Roy. Soc. London B 217, 243 (1983), Creaser et al, BiochemJ. 225 449 (1985), Lockington et al, Mol. Microbiol 1, 275 (1987),Felenbok et al, Gene 73, 385 (1988), Felenbok et al, J. Biotechnol. 17,11 (1991), Kulmberg et al, J. Biol. Chem 267, 21146 (1992), Kulmberg etal, Mol. Microbiol. 7 847, (1993), and Fillinger and Felenbok, Mol.Microbiol 20 475 (1996)) which has only been found in fungi so far. Inaddition, no other plant transcription factors were likely to causeinterference at the alcA promoter. Third, the chemical inducers arerelatively simple organic molecules with low phytotoxicity. Fourth,under normal growth conditions, the levels of natural inducers in theplant would be extremely low.

To test the efficacy of the system, plant expression cassettes wereconstructed. Construction of the alc derived gene constructs. p35S: alcR(A) utilised the 35S promoter from the Cauliflower Mosaic Virus toexpress AlcR protein from a cDNA. A partial alcR cDNA (provided byFelenbok) was excised from its Bluescript vector (Stratagene) by partialdigestion with BamHI, ligated to BamHI digested pJR1 (Smith et al,Nature 334, 724 (1988)), a pUC derived vector containing the CaMV 35Spromoter and the nos terminator, and transformed into E. coli XL-1 Blue(W. O. Bullock et al. BioTechniques 5, 376 (1987); J. Sambrook et al.,Molecular cloning: A laboratory manual, edn. (Cold Spring HarborLaboratory Press, Cold Spring Harbor, New York, 1989). The alcA reportercassette, palcA: CAT (B), was constructed by digestion of pCaMVCN withHindIII and BamHI to remove the promoter. (pCaMVCN is a plant expressionvector available from Pharmacia. It is a pUC—derived vector in which theCaMV 35S promoter expresses the bacterial CAT gene. The terminator isfrom the nos gene of A. tumefaciens.) Since the TATA boxes of the AlcAand 35S promoters were identical (5′TCTATATAA3′), recombinant PCR wasused to amplify and fuse both fragments through this site (Higuchi inPCR Protocols, M. A. Innis et al, eds (Academic Press, San Diego (1990)p177-183 ). The alcA PCR product extended from the TATA box for 246 bpupstream, and included ALCR binding sites ( Pateman et al, Proc. Roy.Soc. London B 217, 243 (1983), Creaser et al, Biochem J. 225 449 (1985),Lockington et al, Mol. Microbiol 1, 275 (1987), Felenbok et al, Gene 73,385 (1988), Felenbok et al, J. Biotechnol. 17, 11 (1991), Kulmberg etal, J. Biol. Chem 267, 21146 (1992), Kulmberg et al, Mol. Microbiol. 7847, (1993), and Fillinger and Felenbok, Mol. Microbiol 20 475 (1996)).The 35S PCR product included the common TATA box sequence and extendeddownstream to span a convenient BamHI site for subsequent cloning; theminimal 35S promoter is known not to be expressed in plants (It has beenshown that a minimal 35S promoter containing only those sequencesbetween positions −46 and +5 lacks the ability to initiate transcription(Odell et al Nature 346, 390 (1985); Hilson et al, Plant Cell 2 651(1990) Schena et al Proc. Natl. Acad Sci USA 88, 10421 (1991). It isreasonable to expect that fusion of palcA through the TATA sequence(positions −31 to +1) would also be inactive.) The resultant product wasdigested with HindIII and BamHI, and ligated into the promoterlesspCaMVCN. After transformation into E.coli, colonies were screened toselect a plasmid which contained the appropriate palcA:35S fusionpromoter, and the HindIII and BamHI fragment was sequenced to ensurethat there were no PCR errors. The palcA::Inv construct was obtained bydeletion of the GUS reporter gene from plasmid palcA GUS and insertionof the truncated yeast suc2 gene isolated from plasmid rolC-suc2 as aBamHI fragment (Lerchl et al (1995) Plant Cell 7, 259 (1995). For planttransformation, the p35S:alcR cassette was cloned into a Bin19-derivedvector (Deblacre et al, Nucleic Acids Res. 13, 4777 (1985), togetherwith either the palcA:CAT or the palcA:Inv construct, transformed intoA. tumefaciens (Holsters et al. Mol. Gen. Genet. 163, 181 (1978);Vervliet et al. J. Gen. Virol 26, 33 (1975)). Tobacco transforming usingAgrobacterium-mediated gene transfer was carried out as describedpreviously (Rosahl et al EMBO J. 6 1159 (1987) and Komari et al PlantScience 60 223 (1989)).

The bacterial chloramphenicol acetyltransferase gene (CAT) was used as areporter gene so that levels of expressed protein could be determinedusing ELISA. When transformed into A. nidulans (Ballance and Turner Gene36, 321 (1983); Campbell et al). Curr. Genet. (1989), the palcA:CATconstruct showed inducible CAT activity, and p35S:alcR restored thewild-type phenotype to an alcR mutant (data not shown). Transient assays(Callis et al Genes and Develop 1 1183 (1987)) in maize protoplastsrevealed that the AlcR protein could stimulate the transcription fromthe alcA promoter in plant cells and that expression was at leastpartially regulated by ethanol (data not shown).

After Agrobacterium tumefaciens mediated transformation a transgenictobacco plant carrying the p35S:alcR and palcA:CAT cassettes wasselected and tested by PCR for the presence of both cassettes (data notshown). This plant was selfed, and the seedling progeny assayed for boththe selectable marker and CAT expression. The construct segregated amongthe progeny in a Mendelian ratio (1 non-transgenic: 2 hemizygous: 1homozygous) consistent with a single copy of the cassettes in the parentplant (data not shown).

A selected seedling was grown to maturity to produce a homozygous line.Seedlings of this plant were tested for CAT protein in comparison toseedlings of a similar plant transformed with a construct whichexpressed CAT from the constitutive high activity CaMV 35S promoter(Table 1). The homozygouspalc:CAT seedlings had barely detectable CATprotein in the absence of induction, but had 39% of the CAT activity ofthe untreated p35S:CAT seedlings and 55% relative to the ethanol-treatedp35S:CAT seedlings. Thus, ethanol treatment of p35S:CAT seedlingsresulted in a reduction [29%] in CAT protein levels relative to theuntreated control.

While the induced levels of expression were lower than that from the 35Spromoter, the negligible basal activity indicated its suitability forthe manipulation of carbon metabolism. A range of inducible invertasevectors were made by replacing the CAT reporter gene with the truncatedyeast suc2 GENE 100, a cytosolic yeast derived invertase. In thisregard, the Bam HI fragment isolated from plasmid RolC::Suc2 (Lerchl etal., 1995, Plant Cell 7, 259-270) was used to replace the reporter gene.The fragment contained nucleotides 848 to 2393 of the yeast such2 gene(Accession number Y01311) and encoded an invertase protein without asignal peptide. Invertases from other sources and of different type,such as acid invertase, or other targeted invertases were also madeusing transit peptide invertase combinations described in Sonnewald etal., 1992, Plant J. 1:95-106 which may be expressed in the cell wall orsubcellular locations such as the vacuole or the apoplast (details ofcloning are described in Caddick et al. Nature Biotech, Vol 16, Feb 1998page 177 and in Lerchl J. et al. 1995, Plant Cell 7: 250-270 andSonnewald et al.). Transgenic tobacco plants carrying palcA:cyInv wereisolated (Tobacco (Nicotiana tabacum cv. Samsun NN) transformation usingAgrobacterium-mediated gene transfer was carried out as described byRosahl et al. EMBO J. 13, 1 (1987) ). After screening about 100independent kanamycin resistant regenerants for ethanol inducibleinvertase activity, 23 invertase expressing plants could be identified.Of 23 plants exhibiting inducible invertase activity, three lines [10,27 and 28] were selected for more detailed analysis. To this end, plantswere multiplied in tissue culture and 50 plants of each line weretransferred into the greenhouse. After 21 days of growth in 2L pots,initial induction was carried out via root drenching with 100 ml of a 1%ethanol solution (v/v). To accelerate the ethanol response, inductionwas repeated at 48 and 72 hours after the initial root drench. To assayinvertase activity, samples were taken at 0, 1, 6, 24, 48, 72 and 96hours after the initial induction (see FIG. 1). Elevated invertaseactivity was measurable in all three transgenic lines already 6 hoursafter the first addition of ethanol. Invertase activity increasedsteadily reaching a plateau 96 hours after the initial root drenching intwo lines [10 and 27], while in the third [28], it was still increasing.

Phenotypic modification started 72 hours after ethanol induction and wasstrongest after 96 hours. The final phenotype was identical to thepreviously published results using the 35S CaMV promoter to drive theexpression of cytosolic yeast invertase (Sonnewald et al Plant J. 1, 95(1991)). Development of this phenotype followed maximal invertaseactivity and was most severe in transformant 28. Photosynthesisfluorescence measurements were used to monitor changes of quantum yield( Schreiber et al, in Ecophysiology of Photosynthesis Vol. 100, Schuizeand Caldwell, Eds (Springer Verlag, Berlin, 1994), pp 49-70.) of allthree transformant lines in vivo throughout the induction experiment.During the course of ethanol treatment, quantum yield did not changemarkedly in the youngest leaves (leaves A 8% of maximal leaf area).However, coinciding with the developing visual phenotype quantum yielddecreased significantly (p >0.05) in leaves B (15% of max) and C (45% ofmax) of plants from line 10 and 28 starting 72 hours after the initialinduction and developing further until the final time point at 96 h.

FIG. 2 shows evidence for a reduced rate of photosynthesis following theincrease of invertase activity in transgenic tobacco plants asdetermined by quantum yield measurements. Fluorescence measurements wereused to monitor changes in photosynthetic parameters during induction ofinvertase activity using the PAM-2000 instrument (Walz, Effeltrich,Germany). Quantum use efficiency (quantum yield) of photosystem II(PSII) was measured by applying a saturating light beam on light adaptedleaves of wildtype and transformed plants (palc:Inv). Before eachmeasurement, it was verified that the saturating pulse had reached aplateau to allow an accurate determination of Fm′. The intensities ofthe measuring and saturating light beam were adjusted to reach a FO′value close to 0.4. Measurements were conducted on different leaveshaving reached 8% (A), 15% (B), or 45% (C) of maximal leaf area of fiveplants of each genotype at the indicated time points.

Quantum yield of three succeeding light adapted leaves (leaf A-C)starting from the top of the plant was measured using a PAM-2000instrument at the time points indicated. Values given are the means +−SE(n=5). For plants of line 28, quantum yield was reduced by 23% (p<0.05)and 27% (p<0.05) and for plants of line 10 only by 6% and 17% (p<0.05),respectively. Due to heterogeneity of the developing phenotype betweenindividual plants from each genotype, standard errors were higher in theaffected leaves (B and C).

The table below shows CAT activity levels in transgenic tobacco.Individual seedlings from a homozygous transgenic tobacco line carryingthe CAT gene expressed from the alcA promoter were compared with thosefrom a similar line transformed with p35S:CAT. Plants were grown onliquid media until 4 weeks old, and showed four true leaves (seedprogeny of tobacco plants were grown by sowing seeds directly onto a 2cm layer of sterile alcathene beads (5 mm diameter) floating on asterile solution of 0.5% (w/v) Miracle Gro in 500 ml beakers. Thebeakers were covered with a perforated plastic bag and incubated at 25°C. under high intensity lights in a growth room). Induction was achievedby the addition of 0.1% ethanol to the growth medium for 120 h. Theinduction medium was replaced at 58 h to maintain ethanolconcentrations. One leaf was taken prior to induction, and one leafafter induction. CAT ELISA (Boehringer Mannheim) was performed on crudecell extracts; total protein was determined as described previously(Bradford, Anal Biochem 72: 243 (1976). All values are ng CAT proteinper mg total protein, and represent the mean of nine individualreplicates±one standard deviation.

Line Untreated Ethanol-induced palcA: CAT 0.36 + 0.43 30.37 + 3.91 p35S: CAT 78.08 + 30.44 55.46 + 10.85

It can be seen from FIG. 3 that the invertase activity in transgenicplants is dose-dependent and that the activity at 5% ethanol issignificantly greater than it is at 1% ethanol. It is, therefore,possible to regulate invertase in a dose dependent manner using the Alcswitch.

In order to see the impact of inducible cytosolic invertase expressionon plant growth and flowering time, tobacco plants were vegetativelypropagated in tissue culture (FIG. 4). Subsequently 50 plantlets eachgenotype were transferred into the greenhouse. In FIG. 4, wt denotes awild type transgenic control and lines 10, 27 and 28 represent 50cloning propagated independent lines containing 35S:alc A:suc 2. Threeweeks after transfer, plants were induced with 100 ml 1% (v/v) via rootdrenching. Induction was repeated three times (0, 48 and 72 hours). Inparticular, FIG. 4 a) shows cytosolic neutral invertase activity (suc 2)measured 96 hours after initial induction, FIG. 4 b) shows fresh weightof the above ground biomass 45 days after transfer and FIG. 4 c) showsplant height 45 days after transfer. FIG. 4 d) shows the percentage ofplants which were flowering when scored 45 days after transfer.

To show the impact of ethanol inducible cytosolic invertase on plantheight and flowering, plants were propagated in tissue culture andtransferred into the greenhouse (FIG. 5). Three weeks after transfer onehalf of the plants were induced with ethanol as described for FIG. 4.The second half of the plants was transferred into a second greenhousewithout any ethanol treatment. The upper panel (A) shows four tobaccoplants 7 weeks after transfer from tissue culture without ethanolinduction. The lower panel (B) shows the same genotypes 4 weeks afterinitial ethanol induction. From left to right the following genotypesare shown: 1, line 27; 2, line 10; 3, line 28; line 4, untransformedcontrol. The early flower phenotype was consistently found in allexperiments.

In order to show that inducible invertase expression leads to anincreased flower number per plant, 25 plants of each genotype (wt, cytinv 10, cy inv 27, cyt inv 28, cw inv 19, cw inv 28 and cw inv 45) werepropagated in tissue culture and transferred into the greenhouse (FIG.6). Three weeks after transfer plants were induced as described above.The total number of flowers produced each plant was determined at theend of the growing period.

As can be seen from FIG. 7, transgenic plants expressing inducibleinvertase have accelerated flower induction. 25 plants of each genotypewere propagated in tissue culture and transferred into the greenhouse.Three weeks after transfer plants were induced as described above.Subsequently, flower formation was followed throughout the growingperiod. Plants were classified as flowering when the first flower budwas open. Values are given in [%] flowering plants per total number ofplants (n=25).

As can be seen from FIG. 8, the early flower phenotype is reproducibleat different growing seasons by means of transient expression ofinvertase. In this regard, 50 (spring) and 25 (summer and autumn) plantsof each genotype were used for the individual experiments, respectively.After propagation, plants were transferred into the greenhouse andinduction started three weeks after transfer as described above. At theindicated time after transfer (dpt, days after transfer) plants withopen flower buds were counted. Values are given in [%] flowering plantsper total number of plants.

Preparation of Plasmid pSTLS1:AlcR:AlcA:GUS (SC08)

To obtain plasmid SC08, the EcoRI/HindIII fragment of plasmid AlcR/A GUScontaining the AlcR coding region and the NOS terminator was subclonedinto pBluescript SK-yielding plasmid pAlcR. Subsequently, plasmid pAlcRwas digested with EcoRI, blunt ended with DNA polymerase (Klenowfragment), further restricted with HindIII and ligated into plasmidpBINSTSL1 after BamHI digestion, Klenow treatment and Hind III digestionyielding plasmid pBIN:STSL1:AlcR. Plasmid pBINSTSL1 consists of theSTSL1 promoter corresponding to nucleotide +1 to +1585 of the publishedsequence of the STSL1 gene from potato (Eckes et al (1986) Mol. Gen.Genet. 205 14-22) and the OCS (octopine synthase) terminator. The finalconstruct SC08 was obtained by ligating the HindIII fragment fromplasmid AlcR/A GUS containing the AlcA promoter, the GUS coding regionand the NOS terminator into the HindIII digested vector pBIN:STSL1:AlcR.The strategy for cloning an Alc GUS construct with the L700 promoter isshown in FIG. 9.

The tissue specific and ethanol inducible GUS expression in transgenictobacco plants i.e. leaf/stem-specific control of the alcR protein isshown in FIG. 10. Trangenic tobacco plants expressing the GUS reportergene under control of the ethanol inducible system were propagated intissue culture and transferred into the greenhouse. Three weeks aftertransfer plants were induced via root drenching using 100 ml 1% ethanol.48 hours after induction tissue samples were harvested and GUS activitydetermined in protein extracts:—sink leaves, <3 cm; source leaves.35S::Alc:GUS, root and stem expression of the alcR protein under controlof the 35S CaMV promoter was used as a constitutive control. L700::Alc:GUS expression of the alcR protein under control of theleaf/stem-specific ST-LS1 promoter from potato in 4 independenttransgenic lines (6, 9, 27 and 74) were also used.

Preparation of Plasmid B33:AlcR:AlcA:GUS (SC09)

To obtain plasmid SC09, the EcoRI/HindIII fragment of plasmid AlcR/A GUScontaining the AlcR coding region and the NOS terminator was subclonedinto pBluescriptSK—yielding plasmid pAlcR. Subsequently, plasmid pAlcRwas digested with EcoRI, blunt ended with DNA polymerase (Klenowfragment), further restricted with HindIII and ligated into theSmaI/HindIII digested plasmid pBIN:B33AlcR. Plasmid pBINB33 consists ofthe patatin class I promoter, corresponding to nucleotide −1512 to +14of the patatin gene B33 (Rocha-Sosa et al. (1989) EBO J. 8 23-29) andthe OCS terminator. The final construct SC09 was obtained by ligatingthe HindIII fragment from plasmid AlcR/A GUS containing the AlcApromoter, the GUS coding region and the NOS terminator into the HindIIIdigested vector pBIN:B33AlcR. A strategy for cloning an Alc GUSconstruct with a patatin B33 promoter is shown in FIG. 11.

Alc R Patatin alc A GUS Vector

pSC09 (B33-alc GUS in Bin 19) was transformed directly intoAgrobacterium tumefaciens strain C58C1:pGV2260 using the protocoldescribed by Hofgen and Willmitzer (1988). Potato (var Solara)transfomation using Agrobacterium-mediated gene transfer was performedas described by Roscha-Sosa et al (1989). Transgenic plants wereduplicated in tissue culture and one set transferred to the glasshousefollowing root formation. Plants were grown to maturity and tubersharvested. For each independent transformant tuber, samples were takenfor GUS analysis in the absence of ethanol treatment. Additional tuberswere transferred to perspex boxes containing a pot of 1% ethanol.Following 7 days of ethanol vapour treatment, tubers were harvested andassayed for GUS activity. FIG. 13 demonstrates that high levels oftransgene expression is observed in the tubers following ethanoltreatment.

Transgenic potato plants expressing the GUS reporter gene under controlof the ethanol inducible system were propagated in tissue culture andtransferred into the greenhouse. Two months after transfer, plants wereinduced via root drenching using 100 ml 1% ethanol. 48 hours afterinduction, tissue samples were harvested and GUS activity determined inprotein extracts:—leaves, stems and tubers >5 g. Pat:GUS expression ofthe GUS reporter gene under control of the class I patatin promoter B33acted as a control. Pat::Alc:GUS expression of the alcR protein undercontrol of the tuber-specific B33 promoter from potato was also used.The activity is given in pmol MU/mg/min. FIG. 14 shows tissue specificand ethanol inducible GUS expression in tobacco plants by tuber-specificexpression of the alcR protein.

The EcoRI and HindIII fragment containing transactivator AlcR gene andNOS terminator was from plasmid 35S:AlcR-AlcA:GUS (35S-Alc:GUS, PlantJournal 1998, 16 (1) 127-132) and subsequently subcloned into BluescriptSK- (STRATAGENE) (AlcR in SK-). The plasmid AlcR in SK- was digestedwith EcoRI and filling-in with Klenow fragment to make it blunt andfurther cut with HindIII. This EcoRI(−)—HindIII fragment was cloned intobinary vector Bin-B33 cut by Small and HindIII resulting in the plasmidpatatin B33:AlcR in pBIN19. The PCR product of yeast invertase withprotein inhibitor II signal peptide (SP) sequence (von Schaewen et al.(1990) EMBO J. 9. 3033-3044) was cloned into pGEM-T vector by primer K83and K84 which containing the Small site. The Small fragment wassubcloned into pUC-AlcA plasmid via BamHI site which was blunted by T4DNA polymerase. The orientation was checked by combining Asp718 andEcoRI, and also with XbaI. The correct orientation plasmid wassubsequently subcloned into patatin B33:AlcR in pBIN19 resulting thefinal plasmid patatin B33:AlcR-AlcA:cwINV in BIN19 (patatinB33::Alc:cwINV). The construction of the plasmid is shown in FIG. 15.

Transgenic potato plants were propagated in tissue culture andsubsequently transferred into the greenhouse. After tuber setting,plants were induced once with 100 ml 1% ethanol (root drenching) andinvertase activity determined in tubers. The left panel shows invertaseactivity prior to (0) and after (1) ethanol induction visualised afterSDS-PAGE. An untransformed wild type was used as a control and comparedagainst independent transgenic lines 2, 3, 4, 5, 7 and 13 (see FIG. 16).

FIG. 17 shows the carbohydrate content of potato tubers two months afterinitial induction. Pat::cwINV, transgenic plants expressing yeastinvertase were placed under control of the tuber-specific B33 patatinpromoter (independent transgenic lines 3, 33 and 41). SC12 (Pat::Alc:cwINV) transgenic plants (independent transgenic lines 2, 5, 7 and13) are ethanol inducible. Tuber-specific expression of cell wallinvertase is caused via tuber-specific expression of the alcR proteinmediated by the B33 promoter.

Transgenic potato plants were propagated in tissue culture andtransferred into the greenhouse. Ethanol induction occurred at threedifferent development stages. 1^(st) induction, 25 days after transfer,2^(nd) induction 32 days after transfer and a 3^(rd) induction 39 daysafter transfer. 10 plants from each genotype were used for eachinduction experiments. Initial induction occurred via root drenching.Due to the induction procedure plants induced after 25 days were vapourinduced 32 and 39 days after transfer. Plants induced 32 days aftertransfer were induced a second time, whereas, plants induced 39 daysafter transfer were induced only once (see FIG. 18).

Other modifications of the present invention will be apparent to thoseskilled in the art without departing from the scope of the invention.

1. A method of increasing the yield of a plant comprising: a. providing a transformed plant with a DNA construct comprising one or more DNA sequence(s) coding for invertase operably linked to an alcA promoter and optionally operably linked to a transcription terminator; and DNA sequence encoding the alcR regulatory protein operably linked to a tissue specific or constitutive promoter; and b. controlling the level, time and spatial location of expression of said DNA sequence(s) from said inducible promoter region by application of an external chemical inducer comprising alcohols or ketones whereby the yield of said transgenic plant is increased. 2-17. (canceled)
 18. Plant tissue transformed with a DNA construct according claim
 1. 19. Plants regenerated from plant tissue according to claim
 18. 20. The method of increasing the yield of a plant according to claim 1 wherein said tissue specific promoter is a tuber specific promoter.
 21. The method of increasing the yield of a plant according to claim 20, wherein said tuber specific promoter is a patatin promoter.
 22. The method of increasing the yield of a plant according to claim 20, wherein said tuber specific promoter comprises −1512 to +14 of the patatin gene B33.
 23. The method of increasing the yield of a plant according to claim 1, wherein said plant is a tobacco plant.
 24. The method of increasing the yield of a plant according to claim 1, wherein said plant is a potato plant.
 25. The method of increasing the yield of a plant according to claim 24, wherein said tissue specific promoter is a tuber specific promoter. 